# Geophysical tests for habitability in ice-covered ocean worlds

**Authors:** Steven D. Vance, Mark P. Panning, Simon St\"ahler, Fabio, Cammarano, Bruce G. Bills, Sharon Kedar, Christophe Sotin and, William T. Pike, Ralph Lorenz, Victor Tsai, Hsin-Hua Huang and, Jennifer M. Jackson, Bruce Banerdt

arXiv: 1705.03999 · 2017-12-06

## TL;DR

This study develops 1-D models of icy ocean worlds to analyze their internal structure and habitability potential, highlighting data gaps and the influence of composition on geophysical properties.

## Contribution

It introduces a framework for modeling internal structures of icy worlds using thermodynamic constraints, revealing key data limitations and potential habitability indicators.

## Key findings

- Ocean compositions vary between oxidized MgSO₄ and reduced NaCl scenarios.
- Gaps in thermodynamic data limit modeling accuracy for certain worlds.
- Different worlds show distinct internal structures and ice phases.

## Abstract

Geophysical measurements can reveal the structure of icy ocean worlds and cycling of volatiles. The associated density, temperature, sound speed, and electrical conductivity of such worlds thus characterizes their habitability. To explore the variability and correlation of these parameters, and to provide tools for planning and data analyses, we develop 1-D calculations of internal structure, which use available constraints on the thermodynamics of aqueous MgSO$_4$, NaCl (as seawater), and NH$_3$, water ices, and silicate content. Limits in available thermodynamic data narrow the parameter space that can be explored: insufficient coverage in pressure, temperature, and composition for end-member salinities of MgSO$_4$ and NaCl, and for relevant water ices; and a dearth of suitable data for aqueous mixtures of Na-Mg-Cl-SO$_4$-NH$_3$. For Europa, ocean compositions that are oxidized and dominated by MgSO$_4$, vs reduced (NaCl), illustrate these gaps, but also show the potential for diagnostic and measurable combinations of geophysical parameters. The low-density rocky core of Enceladus may comprise hydrated minerals, or anydrous minerals with high porosity comparable to Earth's upper mantle. Titan's ocean must be dense, but not necessarily saline, as previously noted, and may have little or no high-pressure ice at its base. Ganymede's silicious interior is deepest among all known ocean worlds, and may contain multiple phases of high-pressure ice, which will become buoyant if the ocean is sufficiently salty. Callisto's likely near-eutectic ocean cannot be adequately modeled using available data. Callisto may also lack high-pressure ices, but this cannot be confirmed due to uncertainty in its moment of inertia.

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/1705.03999/full.md

## References

95 references — full list in the complete paper: https://tomesphere.com/paper/1705.03999/full.md

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Source: https://tomesphere.com/paper/1705.03999